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For some syntactic sugar I want to return a reference to this, but when inherited, the function should return the type of the child class:

class base {
  T &operator!() { return *this; }
};
base b; b = !b;

class child : public base {};
child c; c = !c;

Because of the operator, I can't just return the pointer and dynamic_cast it, it has to be a reference.

Is that even possible? Using decltype(*this) for T doesn't work, neither does auto f()->decltype(*this), because of this (although I don't understand why, in the auto-case)

In Scala you can write something like:

template<typename T> class base {
  T &f() { return *this; }
};
class child : public base<child> {};

But my g++ won't accept this (not sure if that's bug or just not in the spec?)

Of course there's the explicit way, but I wonder if this can be avoided using C++11 features?

class child : public base {
  child &operator!() { base::operator!(); return *this }
};
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Please don't override operators in a way which change their fundamental meanings. It's a really bad idea and will lead to confusion and error. –  Rob K Feb 13 '12 at 18:38
    
in this case it's a DSL thing, I use && actually, and even though it doesn't return a bool, it semantically means "and" –  pascal Feb 13 '12 at 20:53

2 Answers 2

up vote 1 down vote accepted

You can use the CRTP to do this if you're allowed to make base a template:

template <typename Derived> class Base {
protected:
    Derived& refToThis() {
        return *static_cast<Derived*>(this);
    }
};

Note the extra cast here. The reason this works is that if you have a class like this one:

class Subclass: public Base<Subclass> {
    /* ... */
};

Then if you call refToThis from inside that class, it will call the base class version. Since the class inherits from Base<Subclass>, the instantiated template for refToThis will be

    Subclass& refToThis() {
        return *static_cast<Subclass*>(this);
    }

This code is safe, because the this pointer does indeed point to a Subclass object. Moreover, the static_cast will ensure that the cast fails at compile-time if the derived class doesn't inherit from Base properly, as the pointer type won't be convertible.

The reason that the cast is necessary here is that if you just say

template <typename Derived> class Base {
protected:
    Derived& refToThis() {
        return *this;
    }
};

Then there is a type error in the program, since a Base by itself is not a Derived, and if you could convert a Base& into a Derived& without any checks you could break the type system.

That said... I wouldn't do this at all. Overloading operator! for this purpose makes the code less readable, and just writing *this is so idiomatic that hiding it will make your code much harder to understand. Using all of this template machinery to avoid something that's common C++ seems misguided. If you're doing something else before returning the reference that's fine, but this just doesn't seem like a good idea.

Hope this helps!

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thanks, there was some interference in my code that caused an error in the class Subclass: public Base<Subclass> line, I feared this was impossible in C++. –  pascal Feb 13 '12 at 21:01

Please don't do this. There's already a way to do it in the language, *whatever_pointer_you_want_to_use_this_crazy_operator_upon. Creating a new way of doing something in the language will just confuse your future maintainers. Is there something else you're actually trying to achieve here?

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What I actually want to do is a << b << c << d where the << operator is defined in a base class and inherited, however I need the subtype on the left side, unlike ostream –  pascal Feb 13 '12 at 20:57

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